DE4130559A1 - Silencing system with expansion chamber formed in main pipe - incorporates combination of active and passive reflecting surfaces in pipes of different dia. - Google Patents

Abstract

The silencing system damps the sound from a source (8). It consists of a main pipe (1) with an integrally formed expansion chamber (2), and with passive sound reflection surfaces (A,F,C,E). A second device (4a to 4d) is provided and forms active sound reflection surfaces (B,D) in the main pipe (1). The active sound reflection surfaces (B,D) are so formed that they in part permit the through transmission of the sound. The expansion chamber (2) forms a passive sound damper and the passive sound reflecting surface (E) is formed by the end wall of the main pipe (1). USE/ADVANTAGE - Silencing system which is effective over a wide band of acoustic frequencies.

Description

The present invention relates to a sound attenuation system and in particular a sound absorption system according to the preamble of Claim 1.

To reduce noise in a given Lei Spread pipe, are different from the prior art passive silencers of expansion type, of resonance type, of Interference type, sound absorption type and the like are known and in practical use. In these passive silencers, which nem pipe are provided in which the noise wide, is a surface with an inconsistent sound impedance forms, which forms a sound reflection surface through which a part of the Sound energy is reflected to the sound source. Furthermore, such Mufflers suppress the noise by taking advantage of the Interference of the sound wave achieved in the conduit.

From U.S. Patent No. 20 43 416 (1934, P. Lueg) is a so-called "active noise control" known to have an active sound conductance used. In this control a noise or is to be damped one sound to be damped (primary sound) with another sound (Secondary sound) whose phase is opposite that of the primary sound reversed, overlaps. With the Ver Theoretically can drive a perfect for a wide sound frequency band Noise reflection surface and thus a perfect noise suppression be achieved.

Among the various active noise controls currently in use large scope for noise reduction in a conduit system are used, there are procedures on the in the U.S. Patent Disclosed Measure Based. That means the sound pressure of a primary sound at the location of a secondary sound source (approx of a loudspeaker) is calculated by placing one of one in front of the se  secondary sound source (e.g. a micro phon) output reference signal of a digital signal processing is subjected. By using the calculated in this way Neten sound pressure, a secondary sound is generated, the phase ge is reversed compared to that of the primary sound, so the Pri to compensate for sound.

Theoretically, perfect compensation of the primary sound is obtained ten if the amplitude of the secondary sound is equal to that of the Is primary sound and the phase of the secondary sound compared to that is exactly the opposite of the primary sound, d. that is, if the Se sound source creates a perfect sound reflection surface. This means that for a perfect compensation of the primary sound at the location of the secondary sound source, a sound wave blocking area must be created. If theoretically this perfect sound reflex surface is generated, the sound wave cannot converge Spread out the area behind the sound reflection surface. Therefore in In this theoretical case, the secondary sound source is the only one relevant element.

In addition to the active control method mentioned above, K. H. Eghtesadl u. a. in 1983 a so-called "procedure with narrow coupled monopoly "(" Tight-Coupled Monopoly Method ") been hit. In this procedure, a microphone for the Detection of a reference signal and a as a secondary sound source speaker located in the same position. This ver driving has the advantage that it is caused by disturbances in the spread the sound wave in the pipe system is hardly affected and that with it a sound absorption device can be created that has a simple structure. A similar process was launched in 1953 proposed by Olsen.

The methods of the above-mentioned active noise controls However, due to their nature, the following disadvantages.  

First is the frequency band, which is the formation of the perfect Ge noise reflection surface allows, is not sufficiently wide, furthermore the sound absorption is low. This means that a Fre quenzband is generated in which a negative noise reduction (i.e. an increase in noise) occurs. If there is sufficient silencer effect is intended, the arrangement of the ver various elements in the line pipe system complicated what one Pressure loss in the pipe system can result.

Second, the formation of the perfect noise reflection surface is only possible in theory, as mentioned above. Of a The practical point of view is the creation of a real device impossible according to this theory. That means that the device is due an interference of a reflected sound wave behind the secondary Sound source with a sound wave coming from a point in the Line pipe system has been reflected in front of the secondary sound source has no satisfactory sound attenuation.

Third, in the conventional active noise control ver drive that for the derivation of the sound pressure of the primary source on site reference signal normally used by the secondary sound source picked up by a microphone that moves away from the secondary sound source is located. As is known, however, the spreading schema changes characteristic of the sound wave as a function of the temperature of the Gases in the pipe system and the speed at which the gas flows through this conduit system. Through this change characteristic, an error is generated which is then noticed bar if the seconds for the compensation of the primary sound sound is derived. So far this is for mastery an adaptive signal processing is used been. With this processing, however, a quick change can be made the gas temperature and / or speed cannot be controlled. Furthermore, the electrical system for processing the signals complicated.  

Fourth, there is active noise control using the "method closely coupled monopoly "used in making a perfect Form noise reflection surface, as described above is. Therefore, with this control, it is necessary to change the phase of ei Reverse sound signal detected by a microphone and the signal using an amplifier with infinite gain infinitely reinforce. In practice, however, due to Nature of the phase characteristic inevitably an undesirable Os generated. Therefore, a perfect noise reflection surface cannot be created.

The following are the facts by which the conventional sound attenuation systems are negatively affected, listed again:

• 1. The arrangement of the elements is in the passive silencers complicated in the pipe system, resulting in a pressure loss in the System can result.
• 2. The passive silencers that are used to dampen a sound low frequency wave are used inevitably a structure with large dimensions.
• 3. If the passive muffler on a sound wave with a wide Frequency band applied will inevitably be a Frequency band generated in which a negative noise reduction (i.e. an increase in noise) occurs.
• 4. The active silencers proposed so far are aimed at Formation of a perfect noise reflection surface. The training However, such an area is impossible in practice. The means that due to interference of the different elements in the line pipe system including a terminating end of the Sy  stems such silencers are not satisfactory silencers own performance.
• 5. With active silencers of the type in which a microphone for the detection of a reference signal and a speaker for the Generation of a secondary sound in the main pipe from each other which are remote, the spreading scha changes characteristic of the sound wave as a function of the gas temperature in the pipe system and the speed at which that Gas flows through the pipe system. To make this change mastering the characteristic is adaptive signal processing processing has been used. However, for this processing is a very complicated electrical system required, which is why it is very difficult to use this system for practical use to make it fit.
• 6. With the "procedure with a closely linked monopoly", the im Paragraph (5) mentioned disadvantage can be eliminated. With this ver However, due to its nature, driving can be undesirable Oscillations occur.
• 7. For active silencers of the type in which the active elements arranged in a main line pipe of the line pipe system it is necessary to use a material that is against over the gas flowing in the main pipe of the system wi is persistent. This means that in a pipe system, due to the gases with high temperature and / or corrosive gases stream, conventional microphones and speakers do not ver can be applied.

It is therefore the object of the present invention to provide a sound attenuation system to create that the aforementioned disadvantages of conventional sound attenuation systems.  

This task is in a sound damping system of the genus according to the invention solved by the features in the characteristic drawing part of claim 1.

According to the invention, a sound attenuation system is created which a wide sound frequency band a satisfactory sound has damping performance.

Other objects, features and advantages of the invention are in the ne claim and in the dependent claims, which relate to special relate to embodiments of the present invention.

The invention is based on preferred embodiment shapes explained with reference to the drawings; show it:

Fig. 1 is a sound attenuation system according to a first embodiment of the present invention;

Fig. 2 shows a silencing system according to a second embodiment of the present invention;

3A is a graph illustrating an estimated sound attenuation performance of the second embodiment.

3B is a graph illustrating a measured sound attenuation performance of the second embodiment.

Fig. 4 shows a sound attenuation system according to a third embodiment of the present invention; and

Fig. 5 is a graph illustrating the estimated and the measured noise reduction performance of the third embodiment.

In Fig. 1 a first embodiment of the sound-damping system according to the invention is shown.

The noise reduction system according to this embodiment generally comprises a main pipe system 1 having a front and a rear smaller pipe 1 a and 1 b and a forward between these and the rear line tubes 1 a and 1 passive muffler b used (ie, an expansion chamber) contains. As is clear from the fol lowing description, the sound to be damped spreads in the main conduit system 1 in the direction from the front smaller conduit 1 a to the rear smaller conduit 1 b. The passive silencer 2 is equipped with a pair of branched conduit systems 3 a and 3 b, each having an active element 4 a and 4 b. Likewise, the rear smaller line pipe 1 b is equipped with a pair of branched pipe systems 3 c and 3 d, each of which has an active element 4 c and 4 d, respectively.

As shown, these systems and parts are so combined and arranged net that they have a plurality of sound reflection surfaces A, B, C, D, E and F form.

Reference number 8 denotes a primary sound source, to which an inlet end of the main line pipe system 1 is connected.

The active element 4 a, 4 b, 4 c or 4 d of each branched line pipe system 3 a, 3 b, 3 c or 3 d comprises a microphone 5 a, 5 b, 5 c or 5 d, a loudspeaker ( ie a secondary sound source) 6 a, 6 b, 6 c and 6 d and a signal processing and amplification unit 7 a, 7 b, 7 c and 7 d.

It should be noted that the sound reflection surfaces F, A, C and E are of the passive type, while the other sound reflecting surfaces B and D are of the active type. Because of their nature, they are active  Sound reflection surfaces B and D are not perfect noises inflection surfaces.

In each active element 4 , a signal recorded by the microphone 5 is suitably processed and amplified by the signal processing and amplification unit 7 and then output by the loudspeaker 6 .

A tightly coupled, low gain monopoly (hereinafter referred to as LTCM) is used in the present invention. That is, the microphone 5 is attached substantially at the same location as the speaker 6 . The amplification factor of the amplification unit 7 is controlled to a low level, for example to a level below 20 dB, in order to suppress the generation of oscillations. It is noted that the above-mentioned conventional silencing system with the "tightly coupled monopoly" aimed at the formation of a perfect noise reflecting surface has the disadvantage of generating oscillations.

If desired, instead of the LTCM mentioned above, another active element can be used in which the reference signal is detected at a position which is closer to the main line pipe system 1 than to the position of the microphone 5 .

Furthermore, each branched pipe system 3 can also contain a passive element, if this appears desirable. That is, between the microphone 5 and the speaker 6, a pipe or the like can be arranged.

As described above, the active sound reflecting surfaces B and D formed by the active elements 4 are not perfect sound reflecting surfaces, since such a surface is difficult to produce. That is, the reflecting surfaces B and D partially reflect, partially absorb and partially pass through a sound wave.

This means that, according to the invention, interference between the right reflected waves from the active sound reflecting surfaces B and D and positive out of the passive sound reflection surfaces A, C, E and F. is used.

Each branched pipe system 3 has a component that serves to isolate the corresponding active element 4 from the gas flow in the main pipe system 1 .

In order to protect the microphone 5 and the speaker 6 the heat of the flowing in the main pipe system 1 gas of each branched line pipe system 3 is mounted a heat insulating material 9 at an inlet area. If desired, a cooling device can be arranged in such an area in order to ensure thermal protection of this area.

If the gas flowing in the main line pipe system 1 is a high temperature gas and / or a corrosive gas, glass wool or the like is preferably used for the material 9 , which can prevent the gas from penetrating into the branched line system 3 .

It is pointed out that the length of each branched pipe system 3 is determined as a function of the required soundproofing performance and the degree of influence of the gas flowing in the main pipe system 1 . Therefore, if the influence of the gas is negligibly small, the length of the branched pipe system 3 can have the value 0 (zero), whereby a direct attachment of the LTCM to the main pipe system 1 is possible. In this case, an optimal sound damping effect is achieved.

It is also pointed out that not only surfaces F, A and C, which are produced by the expansion and contraction parts in the sound dampers of the expansion type, the resonance type, the interference type and the absorption type, represent discontinuities in the sound impedance, but also the open area E. , which is defined at the end of the main pipe system 1 , form a passive sound reflection surface.

The operation of the silencing system according to the first embodiment of the present invention will now be described with reference to FIG. 1.

The sound wave generated in the primary sound source 8 propagates in the main line pipe system 1 and is formed by the three passive sound reflection surfaces A, C and E, which are formed at the inlet area and at the outlet area of the expansion chamber 2 and at the end of the main line pipe system 1 , and on the two active sound reflection surfaces B and D, which are formed between the pair of branched pipe systems 3 a and 3 b and between the other pair of branched pipe systems 3 c and 3 d, re reflected.

During this sound propagation, an interference occurs between the forward sound waves and the backward sound waves in the main pipe system 1 . When the sound source 8 is subjected to wave reflection, the sound reflection surface F on the inlet side of the main pipe system 1 has a certain effect on the wave interference.

On the active sound reflection surfaces B and D there is a partial one Sound absorption instead.  

As a result, the sound generated by the primary sound source 8 is damped and emitted from the end of the main pipe system 1 .

Modifications of the present invention are described below wrote.

Although it has been described in the above-mentioned first embodiment that the microphone 5 is substantially attached to the position of the speaker 6 , these two devices 5 and 6 can be spaced apart. If desired, adaptive signal processing can be used for signal processing. Furthermore, each branched conduit system 3 can contain a passive element if this appears desirable.

The distance between the microphone 5 and the loudspeaker 6 and their spatial relationship are determined as a function of the sound attenuation required. Therefore, the resonance frequency of the system 3, even at constant ge paused length of the branched pipe system 3 is adjusted by changing 6 the distance and the positional relationship between the microphone 5 and the loudspeaker cher.

For the active element 4 , for example, an arrangement can be used, in which the LTCM is located at the end of a branch pipe 3 each branched off and in which the gain of the LTCM is set to a factor of 0.5. In this case, the end of the branched pipe system 3 has no sound reflecting surface, furthermore, it aims at a uniform sound attenuation characteristic over a wide frequency band of the noise. In this case, there is no restriction on the length of the branched pipe system 3 , so that the reduction in the influence of the gas flow in the main pipe system 1 on the speaker 6 can be easily achieved.

If the characteristic of the signal processing and amplification unit 7 is changed, the characteristic of the sound reflecting surface of each branch pipe system 3 is inevitably changed. For example, if the LTCM is placed at the termination end of the branched pipe system 3 and the gain of the LTCM is set to an appropriate level other than the above-mentioned level (ie, level 0.5), the sound transmission loss of the branched pipe system 3 has a resonance change result. This means that when the gain of the LTCM is changed to a suitable level, the sharpness of the resonance is changed and a reversal between resonance and anti-resonance is achieved. Furthermore, the tuning of the resonance frequency is achieved by changing the phase characteristic of the signal processing and amplification unit 7 .

If desired, more than two branched line pipe systems 3 can be arranged around the passive silencer 2 or around the second smaller conduit 1 b. With such an arrangement, the sound attenuation can be carried out much more effectively without increasing the size of the overall sound attenuation system.

If the characteristic of the sound from the primary sound source 8 is changed to a great extent, the gain factor of the amplifier of each active element 4 and the characteristic of the corresponding signal processing and amplifying unit 7 should be controlled as a whole.

If desired, the expansion chamber 2 of the silencing system can be filled with a sound absorption and heat insulation material such as glass wool or the like to increase the silencing effect of the system.

In FIG. 2, a second embodiment of the sound-damping system according to the invention is shown.

In this second embodiment, no device is provided which corresponds to the expansion chamber 2 in the first embodiment of FIG. 1. As shown in Fig. 2, two branched line pipe systems 3 e and 3 f are arranged at an axial distance from the main line pipe system 1 , which form the active sound reflection surfaces B and D bil. Therefore, two active sound reflecting surfaces B and D and one passive sound reflecting surface E are provided in this embodiment.

FIG. 3A shows a graph illustrating the estimated performance of the sound attenuation system according to the second embodiment of FIG. 2. The curve drawn with a broken line represents the estimated attenuation achieved with the second embodiment, while the other curves drawn with a solid line and a dotted line, respectively, represent the estimated attenuations from other sounds Attenuation systems of a type similar to the second embodiment are achieved, wherein one system (the system which shows the power represented by the solid curve) is a system with three active sound reflecting surfaces and the other system (ie the system which is illustrated by the dotted curve) Performance shows) is a system that only has an active sound reflection surface.

From this graph it is clear that in a system with only one active sound reflection surface periodically very narrow Damping zones occur. With increasing number of active sound however, these unwanted areas tend to ver wane. This means that even if none of the active ones Sound reflecting surfaces is a perfect sound reflecting surface, one too satisfactory damping is achieved when a plurality of acti ven sound reflection surfaces is combined.  

FIG. 3B shows a graph which illustrates the measured performance of the sound attenuation system according to the second embodiment of FIG. 2. That is, the broken line curve illustrates the measured attenuation achieved by the system of the second embodiment, while the solid line curve shows the estimated attenuation achieved by the second embodiment. The length of each branched pipe system 3 was 10 mm, so that the length could be neglected with respect to the measuring range. The graph of FIG. 3B shows that there is a significant correlation between the estimated power and the measured power.

In Fig. 4 shows a third embodiment of the sound-damping system according to the invention is shown.

This embodiment is substantially the same as the second embodiment except that an expansion chamber is provided. That is, in the third embodiment, part of the main piping system 1 , on which the piping system 3 e branched in the forward direction is located, forms an expansion chamber 2 . Therefore, in this embodiment, two active sound reflecting surfaces B and D and three passive sound reflecting surfaces A, C and E are formed. If desired, the expansion chamber 2 may be filled with a sound absorption and heat insulation material such as glass wool or the like to promote the sound damping effect of the sound damping system.

FIG. 5 shows a graph which illustrates the estimated and the measured performances of the sound attenuation system according to the third embodiment of FIG. 4. That is, the curve drawn by a solid line represents the estimated attenuation achieved by the third embodiment, while the curve drawn by a broken line represents the measured attenuation achieved by the third embodiment. For comparison, two further results are shown in the graph. The curve drawn with a dotted line shows the estimated attenuation achieved by a system which only comprises the passive sound reflecting surfaces A, C and E, while the curve drawn with a chain line shows the measured attenuation achieved by this system. From the graph of FIG. 5 it is clear that there is a considerable correlation between the estimated power and the measured power.

It is also clear from the graph of FIG. 5 that satisfactory attenuation in a wide frequency band can be achieved by creating the active sound reflection surfaces.

Claims (18)

1. Sound damping system for damping the sound from a sound source ( 8 ), with
a main conduit ( 1 ) through which the sound from the sound source ( 8 ) propagates, and
a first device ( 2 ), with which at least one passive sound reflection surface (A, F, C, E) is defined in the main conduit ( 1 ),
characterized in that
a second device ( 4 a to 4 d; 4 e, 4 f) is provided in order to define a plurality of active sound reflection surfaces (B, D) in the main conduit ( 1 ), and
the active sound reflecting surfaces (B, D) are designed in such a way that they partially let the sound through. 2. Muffler system according to claim 1, characterized in that the passive sound reflection surface of the first device forms part of a passive muffler ( 2 ). 3. Acoustic damping system according to claim 1, characterized in that the passive sound reflection surface (E) is defined at a closing end of the conduit ( 1 ). 4. Muffler system according to claim 2, characterized in that the passive muffler ( 2 ) is of the expansion type. 5. Sound absorption system according to claim 4, characterized in that the expansion muffler ( 2 ) is filled with a Schallab sorption material. 6. Sound absorption system according to claim 1, characterized in that each of the active sound reflection surfaces (B, D) of the two-th device ( 4 a to 4 d; 4 e, 4 f) is provided with a branched pipe system, which comprises:
a branched pipe ( 3 a to 3 d; 3 e, 3 f) connected to the main pipe ( 1 ),
a sound detection sensor ( 5 a to 5 d; 5 e, 5 f), which is arranged in the branched conduit ( 3 a to 3 d; 3 e, 3 f), based on a signal from the sound source ( 8 ) Capture reference signal
a secondary sound source ( 6 a to 6 d; 6 e, 6 f), which is arranged in the branched branch pipe ( 3 a to 3 d; 3 e, 3 f), in order to then output a secondary sound when it is actuated , and
a signal processing unit ( 7 a to 7 d; 7 e, 7 f) which actuates the secondary sound source ( 6 a to 6 d; 6 e, 6 f) on the basis of the processing of the reference signal. 7. Sound absorption system according to claim 6, characterized in that the secondary sound source ( 6 a to 6 d; 6 e, 6 f) is arranged at a terminating end of the branched conduit ( 3 a to 3 d; 3 e, 3 f) . 8. Sound absorption system according to claim 6, characterized in that the length of each of the branched conduits ( 3 a to 3 d; 3 e, 3 f) is approximately 10 mm. 9. Sound attenuation system according to claim 7, characterized in that at least two (3a, 3b; 3c, 3d) of the branched Lei pipe systems ( 3 a to 3 d) of the second device ( 4 a to 4 d) in substantially the same section of Main pipe ( 1 ) are net angeord. 10. Sound attenuation system according to claim 6, characterized in that the sound detection sensor ( 5 a to 5 d; 5 e, 5 f) and the secondary sound source ( 6 a to 6 d; 6 e, 6 f) in the branched conduit ( 3 a to 3 d; 3 e, 3 f) are arranged in substantially the same position and the signal processing unit ( 7 a to 7 d; 7 e, 7 f) is set to a relatively low gain. 11. Sound absorption system according to claim 10, characterized ge indicates that the gain is approximately 0.5. 12. Sound attenuation system according to claim 10, characterized in that the signal processing unit ( 7 a to 7 d; 7 e, 7 f) has a phase inversion characteristic and a resonance frequency Va riierungse property. 13. Sound attenuation system according to claim 7, characterized in that the sound detection sensor ( 5 a to 5 d; 5 e, 5 f) and the secondary sound source ( 6 a to 6 d; 6 e, 6 f) essentially on the same Chen position are arranged and the signal processing unit ( 7 a to 7 d; 7 e, 7 f) is set to a relatively low gain. 14. Sound attenuation system according to claim 6, characterized in that between the sound detection sensor ( 5 a to 5 d; 5 e, 5 f) and the secondary sound source ( 6 a to 6 d; 6 e, 6 f) a passive element is installed is. 15. Sound attenuation system according to claim 6, characterized in that the signal processing unit ( 7 a to 7 d; 7 e, 7 f) is so created that it can perform adaptive signal processing by which the output from the unit depending on the characteristic of the reference signal from the sound detection sensor ( 5 a to 5 d; 5 e, 5 f) is completely corrected. 16. Sound damping system for damping the sound from a sound source ( 8 ), with
a main conduit ( 1 ) through which the sound from the sound source ( 8 ) propagates, and
a passive muffler ( 2 ) which is functionally arranged in the main pipe ( 1 ) and defines at least two passive sound reflection surfaces (A, C) on the front and rear sections of the passive muffler ( 2 ),
characterized in that
a pair of branched line pipe systems ( 3 a, 3 b) is provided, which are arranged on the passive silencer ( 2 ) in order to define an active sound reflection surface (B) in the passive silencer ( 2 ), each branched line pipe system being connected to the main line pipe ( 1 ) connected branched pipe ( 3 a, 3 b), in the branched pipe ( 3 a, 3 b) arranged sound detection sensor ( 5 a, 5 b) for detecting a reference signal based on a signal output by the sound source ( 8 ) , a secondary sound source ( 6 a, 6 b) arranged in the branched conduit ( 3 a, 3 b) for the output of a secondary sound when it is actuated, and a signal processing unit ( 7 a, 7 b) for actuating the secondary sound source ( 6 a, 6 b) based on the processing of the reference signal and
the branched pipe systems ( 3 a, 3 b) are constructed in such a way that the created active sound reflection surface (B) in the passive silencer ( 2 ) partially lets the sound through. 17. A silencing system according to claim 16, characterized by a further pair of branched pipe systems ( 3 c, 3 d), which are arranged on the main pipe ( 1 ) at a position behind the passive silencer ( 2 ) in order to be active in the main pipe ( 1 ) Define sound reflection surface (D). 18. Sound attenuation system according to claim 17, characterized in that the branched conduit systems ( 3 c, 3 d) of the further branched conduit system are constructed so that the active sound reflection surface (D) created in the main conduit ( 1 ) partially passes the sound through.